JPH0750960B2 - Improvement of loudspeaker enclosure - Google Patents

Description

TECHNICAL FIELD OF THE INVENTION The present invention relates to loudspeaker enclosures.

Prior Art Acoustic output from a loudspeaker system includes acoustics from one or more loudspeaker drive units as well as acoustics caused by vibrations of the enclosure wall.
The enclosure inevitably has a resonance frequency, and the intensity of the sound produced by the vibration of the enclosure wall is greater at some frequencies than at other frequencies, and thus the timbre of the acoustic output (co
loration).

Reducing such timbre involves reducing the amplitude of vibration of the enclosure wall for a given excitation level, but such amplitude is mainly due to the stiffness of the enclosure at low frequencies. And, at high frequencies, mainly by the mass per unit area of the wall. Conventional loudspeakers are made to have quite thick wooden walls for the purpose of providing adequate rigidity and high mass per unit area. The large mass per unit area has the advantage of reducing the vibration frequency at high frequencies, but it has two significant drawbacks, which are due to the enclosure wall forming a resonant system. Of.

The first drawback of increasing the mass per unit area of the enclosure wall is that the Q-value, including the longer "echo time", increases. By analogy with the values used for room acoustics,
The reverberation time of a loudspeaker enclosure can be defined as the time when the vibration amplitude of the wall decays by 60 dB after the excitation has ended. By this definition, a reverberation time of up to 0.3 seconds is not unusual for a normal enclosure with wooden walls.

A second disadvantage of increasing the mass per unit area of the enclosure wall is that the resonance frequency is reduced. Considering first the loudspeaker enclosure with only one drive unit, the amplitude of the air pressure oscillations within the enclosure decreases as the drive unit oscillation frequency increases. Therefore,
The walls are more “actuated” at low frequencies, resulting in lower frequency resonances being more severe than higher frequency resonances. For the sake of simplicity, if there are just two drive units, the low frequency signal will be fed to the drive unit exclusively or mainly (usually referred to as the "woofer" or bass loudspeaker) and the high frequency signal will be Drive unit exclusively or mainly for the other (usually "tweeter")
That is, the so-called split circuit (cross-over net) which is designed to be applied to a high-pitched loudspeaker
In the case of a loudspeaker enclosure with two or more drive units where signals are provided through the work), the air adjacent to the rear surface of the diaphragm of the treble loudspeaker communicates with the air in the main part of the enclosure. There is an additional factor in ensuring that the treble loudspeaker does not do it. Therefore, the enclosure wall is not activated to any significant extent at frequencies substantially above 3 KHz, which are handled essentially only by high-pitched loudspeakers.

Based on the above analysis, it has been proposed to use two thin aluminum sheet-shaped materials which are separated by a honeycomb structure of, for example, an aluminum alloy, as a constituent material of the loudspeaker enclosure wall. Such materials have a large stiffness-to-mass ratio, which gives rise to a higher resonant frequency than that of conventional wood cabinets. Higher resonant frequencies give shorter reverberation times if the Q-factor is assumed to remain constant. Because the Q-factor is inversely proportional to the% loss per cycle of energy of the system caused by the vibration of the oscillating system, the higher the frequency, the more cycles there are and therefore the larger the ratio. Vibrational energy is lost per unit time. In fact, the rigidity of the wall −
Increasing the mass ratio also increases the Q factor, but only to the extent that it only partially offsets the decrease in echo time caused by the high resonant frequency. Therefore, the net effect of the increased stiffness-mass ratio of the wall is to reduce the reverberation time of the enclosure. However, difficulties occur due to the so-called coincidence effect.

The theory underlying this coincidence effect is a little complicated, and is due to the ability of the enclosure wall to transmit the sound produced in the enclosure by the rear surface of the drive unit (not by wall vibration). It is convenient to think about the effect.
The coincidence effect, which is not a simple resonance phenomenon (in that it does not occur at a single frequency), manifests itself in an increase in the ability of the wall to transmit sounds with frequencies above a certain critical frequency.

Such a critical frequency is directly proportional to the square root of the mass per unit area of the wall and inversely proportional to an amount that is a measure of the wall's flexural rigidity. Therefore, for walls with a low stiffness-mass ratio, the critical frequency is low and the coincidence effect becomes a significant drawback. It has therefore been proposed to fill a loudspeaker enclosure with such a wall at least partly with a sound-absorbing material to reduce the amplitude of the sound waves incident on the inner surface of the wall.

The Applicant has conducted tests to investigate the timbre caused by vibration of the walls of the loudspeaker enclosure. These tests measure the acoustic level from the housing wall absolutely for a given input signal and relative to the acoustic level from one or more drive units,
It was designed to measure the reverberation time of the enclosure and confirm the different levels of sound from the housing wall and the inherent effects of different reverberation times. Below is a brief overview of the procedure for these tests.

A number of differently constructed loudspeaker enclosures each underwent a series of tests. In the first test, the loudspeaker is placed in an echo chamber and the entire sound from the loudspeaker system, ie sound from one or more units and sound from the enclosure wall, is picked up by a microphone in the room. Was given. The signal applied to the loudspeaker was pink noise (random noise with equal energy per octave over the frequency band under investigation) and the output from the microphone was applied to the spectrum analyzer.

Such a test is performed on the front of the loudspeaker enclosure,
An enclosure similar to this loudspeaker enclosure was repeated with the loudspeaker enclosure mounted in a sealed condition except that the drive unit was removed in line with this. The output from the spectrum analyzer at this time shows the sound emitted only by the walls of the double housing thus created, the level of this sound being that of the wall of the original loudspeaker enclosure. It is a good approximation to the sound level produced by vibration alone, and thus, for this sound level, ie the strength of the signal given to the loudspeaker and for the sound level from the drive unit. Was confirmed.

A loudspeaker enclosure different from the original loudspeaker system, having one or more drive units shielded by a second enclosure as described above, was used for the rest of the test.

In the second test, a "shielded" loudspeaker was placed in an anechoic chamber with a microphone.
A signal indicating the sound emission is given to the loudspeaker,
The weakening of the output signal from the microphone was tested to confirm the echo time of a "shielded" loudspeaker, which is a good approximation of the echo time of the wall of the original loudspeaker enclosure. Could be shown.

In the third test, the loudspeaker was again placed in an anechoic chamber with a microphone and a music signal was applied to the loudspeaker, for example from a small disc player. The same signal was given to the headphone worn by listeners outside the room. The output from the microphon was mixed with the original signal being applied to the headphone at a level lower than the original signal level to the extent determined by the first test. The mixed level of the signals from the microphones can of course be changed above or below the level considered to be the correct level, i.e. the level determined by the first test, the signal from the microphones also being added, Or to be removed (switch
I was able to switch in or out).

Not only did these tests confirm that it was desirable to have a low level of acoustic power output to the housing wall and a short reverberation time, but they did not substantially impair the inherent effects experienced by the listener. We have determined that the maximum allowable sound level from the body wall increases with decreasing echo time.

OBJECTS OF THE INVENTION The present invention seeks to further improve the performance of prior art loudspeaker enclosures as described above.

SUMMARY OF THE INVENTION The present invention comprises a top and bottom wall, a front wall and a back wall, a left wall and a right wall, each of which is formed by a wooden panel in a rectangular box-shaped housing, Located within the housing and extending from the top wall to the bottom wall and from the left wall to the right wall, the planes of which are substantially parallel to each other and to the pair of opposing housing walls. A first set of spaced-apart stiffening panels and the faces thereof are arranged parallel to each other and substantially parallel to the opposite pair of opposing housing walls. A hollow reinforcing structure adapted to include a second set of reinforced panels disposed between said first set of reinforced panels and being substantially rigidly fixed to said second reinforced panel. As orthogonal to these second reinforcement panels So that the reinforcing panel forms a number of rectangular parallelepiped compartments with the housing wall, and holes are provided in the reinforcing panel to provide communication between adjacent compartments. A loudspeaker enclosure is provided.

Based on the above-mentioned analysis and the results of the above-mentioned Applicant's tests, the reinforcement panel of the loudspeaker enclosure according to the present invention has a low frequency (below the lowest resonance frequency), as compared to a conventional loudspeaker enclosure with wooden walls. ) Gives a slight reduction in the amplitude of the vibration of the enclosure wall, but in any case the improvement is not significant enough to justify the increased complexity of the structure and the enclosure wall per unit It was expected that the inherent improvement in performance, if any, would be small due to the long reverberation times that would be expected of a wood panel that inevitably had a relatively large mass of. In particular, it was expected that the intrinsic performance would be no better than that of the previously proposed metallic Sangertian structure, as described above, at least below the critical frequency of the enclosure. Surprisingly, the tests along the lines above not only show that the stiffening panel not only reduced the amplitude of the enclosure wall vibration at low frequencies, but also substantially reduced the reverberation time and substantially reduced the original performance. It proved that the improvement result was obtained. The reduction of the echo time indicates that the stiffening panel significantly increases the damping, but the mechanism for increasing the damping is not completely understood at present.

Advantageously, at least one of the sets of stiffening panels is of unitary construction and spans the interior of the housing. When one of the sets of the reinforcement panels has a one-piece structure and the inside of the housing is passed over, the other of the sets of the reinforcement panels is provided with a strip. Made, some of which extend between the adjacent panels of the one set and are secured to these panels, with the remaining strip extending between the panels of the one set and the housing wall. Then, they are fixed to these panels and the housing wall. The strips that form one given stiffening panel need not be, although they are, in fact, flush. However, the reinforcing panels of both of the sets of reinforcing panels are integrated structure and pass through the inside of the housing, and each reinforcing panel has a groove, and the groove of the reinforcing panel of each set is the same as the reinforcing panel of the other set. It is desirable to be made to accept.

Advantageously, one set of stiffening panels is fixed to the other set of stiffening panels. The reinforcement panels are preferably adapted to be secured together by an adhesive.

The stiffening panel is advantageously made of wood and is preferably made of hardboard. Plywood is another desirable material. The thickness of such a wooden stiffening panel will vary depending on the dimensions of the housing and the spacing between adjacent panels of each set, but a thickness of 2 to 6 mm is usually found to be suitable. Has been issued.

Instead of using wooden stiffening panels, stiffening panels of plastic material can also be used, in which case the hollow stiffening structure can be of unitary construction. In this way, the hollow reinforcing structure can be formed by injection molding.

The stiffening panel is advantageously fixed to the housing wall. If the reinforcement panel is fixed to the housing wall,
These stiffening panels are brought into tension or compression, resulting in increased efficiency. Advantageously, the stiffening panel is fixed to the housing wall by means of an adhesive, the adhesive used is not brittle and
An adhesive that can be fixed in a rubbery state is desirable. An adhesive of this type which has been found to be satisfactory is a polyvinyl acetate adhesive. The same idea applies when selecting the adhesive used to secure one set of wooden stiffening panels to the other set of wooden stiffening panels.

As explained above, the mechanism by which the stiffening structure damps the vibrations of the housing wall is not completely understood, but for the purposes mentioned above adhesives are used to fix it in a rubbery state rather than a brittle state. If so, such an adhesive substantially contributes to the damping provided by the reinforcing structure.

The inner surface of the housing wall, which is not designed to receive the stiffening structure and at least the drive unit, can be sprayed with a sound deadening substance, which also secures the edges of the stiffening panel to the housing wall and reinforces it. If the structure is not a unitary structure, it serves to secure one set of stiffening panels to the other set of stiffening panels. Asphalt and filler mixed biomaterial materials have been found to be suitable for this purpose, which also contribute substantially to the damping provided by the reinforcing structure.

For a set of panels that serve as a reinforcing structure, it is recognized that these panels must be a tight fit within the housing, or the edges of the panels must be secured to the housing wall. Furthermore, at least as a general rule, adhesives that have been found to work satisfactorily with wood panels require wood-to-wood contact. To avoid the need for tight tolerances as otherwise required to obtain tight tolerances, the edges of the stiffening panel can be received in grooves in the housing wall. In that case, it is only necessary that the thickness of the reinforcing panel be correctly related to the width of the groove.

Advantageously, the compartment bounded by the stiffening panel is of substantially square cross section with the housing wall.
In that case, each housing wall is reinforced by the reinforcing panel in substantially equal intervals in two directions parallel to the two pairs of opposed edges of the wall.

Advantageously, each said set of stiffening panels comprises at least three stiffening panels, preferably one set of said sets consisting of at least five stiffening panels. It is possible to increase the number of reinforcing panels used and / or increase their thickness when starting from a loudspeaker enclosure of one given size to a significantly larger size .

Advantageously, at least some of the compartments contain acoustically absorbing material. It has often been found that it is desirable that at least a majority of the compartments contain such material, and that all compartments be arranged such that they contain such material. The considerations relating to these are described below in connection with the loudspeaker system described below with reference to the accompanying drawings. The sound absorbing material may be in the form of blocks of open cell plastics material, suitably open cell polyester foam blocks or open cell polyether foams. Alternatively to the above, the sound absorbing material can be in the form of glued acoustic fibers, waste wool, rock wool or glass fibers.

A front surface of the loudspeaker enclosure is arranged to receive at least one loudspeaker drive unit,
Advantageously, one set of stiffening panels lies parallel to the side walls of the housing and the other set of stiffening panels lies parallel to the top and bottom walls of the housing.

The housing wall is advantageously made by a particle board, sometimes referred to as a chipboard. It is made from wood particles or chips embedded in a resin matrix and has a high density. The veneers are usually placed on the outer surface of the wall.

Suitable thickness for wooden housing walls is usually 10 to 20
In the range mm, a suitable mass per unit area of wall is in the range 7 to 12 kg per m ² .

The invention also provides a loudspeaker enclosure according to the invention with one or more loudspeaker drive units mounted in the housing wall. One wall of the housing with one or more loudspeaker drive units may also be vented so that the loudspeaker enclosure constitutes a Helmholtz resonator.

Two loudspeaker systems constructed in accordance with the present invention are described below by way of example with reference to the accompanying drawings.

DETAILED DESCRIPTION OF THE INVENTION A first loudspeaker system constructed in accordance with the present invention includes a loudspeaker enclosure and two loudspeaker drive units. The loudspeaker enclosure includes a number of intersecting stiffening panels forming a compartment structure. All compartments contain acoustically absorbing material and the holes in these panels are adapted to provide communication between adjacent compartments. The intersecting stiffening panels are formed by hardboards, each compartment having a square cross-section when viewed in front elevation. The entire compartment structure is rigidly fixed together by the use of glue at the intersections, and also rigid on the enclosure walls except where not disturbed by the loudspeaker drive unit and vents. It is fixed to. Grooves are formed in the enclosure wall to receive the free edges of the compartment structure, which edges are secured within the groove by an adhesive. The preferred adhesive used to construct the enclosure is PVA.
(Polyvinyl acetate) adhesive. The sound absorbing material is a foamed synthetic resin material, and the foamed synthetic resin material is made into a block shape and inserted into the individual compartments.

Referring to the drawings and in particular to FIG. 1, a loudspeaker enclosure includes a rectangular box-shaped housing generally indicated at 100, which includes a top wall 102, a bottom wall 104 and a front wall (not shown). ), Rear wall 106, left side wall 108, right side wall 110
Consisting of and each of these walls is a wooden panel. Each panel is veneered approximately 15 mm thick and has a mass per unit (including veneers) of about 9 kg per m ² . The front wall is omitted in FIG. 1 to show the inside of the enclosure. A pair of loudspeaker drive units (not shown) are mounted on the front wall in the conventional manner. The wooden wall forming the housing wall is made of hardboard.

Hollow reinforcement structure, generally designated by the numeral 200, is the housing 1
Located in 00, but due to the free space near the loudspeaker drive unit and the circular vents, the locations of which are shown by the circle 330 in FIG. 9 and detailed below. There is room for. Hollow reinforcement structure 200
Is fixed in place by an adhesive and the top wall 102 and the bottom wall 104
In addition, a front wall (not shown) is rigidly connected to the rear wall 106 and a left side wall 108 is rigidly connected to the right side wall 110. Hollow reinforcement structure 200
Consists of three panels 1, three panels 2 and three panels 3 (discussed further below), the planes of which are arranged parallel to each other and parallel to the top wall 10 and the bottom wall 104 respectively. The first set of nine spaced reinforcing panels and two panels 4 and two panels (hereinafter the loudspeaker system was adapted to extend horizontally in the normal orientation) And the planes thereof are arranged parallel to each other and parallel to the left side wall 108 and the right side wall 110, respectively, whereby the loudspeaker system extends vertically in the normal orientation position. A second set of four spaced reinforcement panels. The first set of horizontal stiffening panels 1, 2 and 3 intersects with the second set of vertical stiffening panels 4 and 5 by using an adhesive at these crossing positions for these panels. It is rigidly fixed. A number of rectangular parallelepiped compartments 250 are made in this way. Circular hole (detailed below)
Are formed in the stiffening panel to provide communication between adjacent compartments, all compartments including acoustically absorbing material (not shown in FIG. 1) as detailed below. .

The shapes of the reinforcement panels 1 to 5 are shown in FIGS. 2 to 6, respectively. The loudspeaker enclosure comprises three reinforcing panels 1 having the shape shown in FIG. 2, three reinforcing panels 2 having the shape shown in FIG. 3, and three reinforcing panels having the shape shown in FIG. 3 and 2 of the shape shown in FIG.
One reinforcement panel 4 and three reinforcement panels 5 having the shape shown in FIG. 6 are used. All reinforcement panels 1,
2,3,4,5 are made by 3mm thick hardboard.

Each reinforcement panel 1 is roughly rectangular in outline and has a length of 255 mm and a width of 230 mm. Each reinforcement panel 1
One lateral edge of which has a centrally arranged rectangular recess 11 of size 15 × 73 mm, with four grooves 12 parallel to each other and parallel to the longitudinal axis of the stiffening panel. It starts at the edge and ends half way along the length of the reinforcement panel. The two outermost grooves open to the lateral edge and the two innermost grooves open to the recess 11. Each groove is 3 mm wide and is symmetrically arranged about the longitudinal axis of the stiffening panel, with the groove axes spaced at 46 mm pitches. Each reinforcement panel 1
Contains 27 circular openings 13 with a diameter of 19 mm, the centers of which are arranged in five rows with a longitudinal spacing of 42 mm and a lateral spacing of 46 mm. These openings
The array of 13 is a stiffening panel except that it does not have the three openings near the recess 11 required in the case of a perfectly symmetrical array so as to avoid getting too close to the edges of the material. 1 is symmetrical about the lateral and longitudinal axes.

The reinforcing panel 2, only one of which is shown in FIG. 3, is provided only with a larger rectangular recess 21 and with 20 openings 23 arranged in four 5 rows. Is different from the reinforcing panel 1. The recess 21 has a size of 90 × 186 mm, and four grooves 22 are open to this recess. All other dimensions are the same as those given for the stiffening panel 1, and the material is also hardboard.

The reinforcing panel 3, only one of which is shown in FIG. 4, differs from the reinforcing panel 1 only in that it is provided with recesses 31 of different dimensions and is provided with 28 openings 33. Four grooves 32 are provided, the dimensions are the same as those given for the panel 1 and the material is also hardboard.

The reinforcement panels 1, 2 and 3 extend horizontally within the loudspeaker enclosure, while the reinforcement panels 4 and 5 extend vertically.

Each stiffening panel 4 (see FIG. 5) is roughly rectangular in outline and has a height h of 450 mm and a depth d of 255 mm and is made by a hardboard 3 mm thick. One side edge of the long edge of each reinforcing panel 4 has a symmetrically centrally arranged recess 41 and nine open-ended grooves.
42 extend inwardly from the other long edge of the panel parallel to each other and parallel to the short edge of the stiffening panel. Each groove 42 has a length equal to half the depth of the reinforcing panel 4. The recess 41 has a trapezoidal shape,
It has a rear wall 41 'parallel to the longitudinal axis of the stiffening panel 4 and forming one of the parallel sides of said trapezoid. This trapezoidal side wall 41 ″ expands toward the one side edge of the reinforcing panel 4, the expansion angle α is 20 °. The opening of the recess 41 is 134 m.
It has a length m of m and this recess has a depth n of 90 mm.
The stiffening panel 4 comprises 52 circular openings 43 of diameter 19 mm, the centers of these openings being spaced longitudinally by a pitch of 45 mm and laterally by a pitch of 42 mm, respectively. The arrangement of these openings 43 is such that the openings in relation to the eight additional openings required to obtain perfect symmetry are not provided because of the recess 41, but in the lateral direction of the reinforcement panel 4. And symmetrical about the longitudinal axis. Each groove 42 had a width of 3 mm and the axis of the groove had pitches spaced at 45 mm.

The reinforcing panel 5, only one of which is shown in FIG. 6, is provided with recesses 51 of different shape, an additional recess of rectangular shape.
55 is provided, and 44 openings 53 are provided in consideration of the recesses 51 and 55, and are different from the panel 4. Nine grooves 52 are provided in the same manner as the grooves 42. The recess 51 is a rear wall 51 'parallel to the longitudinal axis of the reinforcing panel 5.
And the bottom side wall 51 "parallel to the lateral axis of the reinforcement panel
And the side wall 51 ″ has an oblique side wall 51 that expands toward the mouth of the symmetrical recess, the expansion angle β of which is 10 °.

The rectangular recess 55 has the dimensions of 15 × 56 mm and its top edge (6th
(As seen in the figure) is spaced 27.3 mm from the top of the reinforcement panel 5.

Considering now the recess 51, the outermost end of the side wall 51 of this recess is at a distance of 135 mm from the top edge of the reinforcing panel 5, and the side wall 51 ″ of the recess is at a distance of 408 mm from the top edge. The recess 51 has a depth of 90 mm.

All other dimensions are the same as those given for the stiffening panel 4, the material also being heartboard.

The thirteen stiffening panels described above are fitted together by grooves to form a composite structure of intersecting stiffening panels as shown in FIG.
Is configured. At each intersection, the vertical reinforcement panel groove receives the horizontal reinforcement panel thickness up to its end, and the horizontal reinforcement panel groove receives the vertical reinforcement panel thickness. . Recesses 11, 21, 31, 41, 51 and 55 bound the space housing the rear of each drive unit of the system and the space near the ventilation holes.

It is possible to assemble these 13 stiffening panels into stiffening structure 200 using an adhesive at each intersection and then introduce the completed structure into housing 100. It is desirable that one of the five be fitted only once in a mating groove (not shown) provided in the housing wall. Reinforcement panels 1, 2 and 3 are provided with housing 100 with the front wall of housing 100 removed, instead of having the pants inserted into the trouser chest.
It can be inserted into it, after which the reinforcing panels 4 and 5 can be grooved in place. The reinforcing structure 200 that defines the interior surface and compartments of the housing 100 may be adhered to the subsequently intersecting reinforcing panels to each other and to the wall of the housing 100 (when no other adhesive is used), or if desired. A vibration dampening compound, such as a liquid biostatic material, which serves as an adhesive to help with the can be sprayed.

A sound absorbing material in the shape of each block 300 of synthetic resin foam is inserted into each section 2520 of the reinforced structure 200. Schematic assembly drawings are shaded by 50
It is shown that any of the compartments 250 of FIG. 2 receives a foam block of dimensions 42 × 42 × 250 mm, while the other compartment (not shaded) has a short block inserted. A circle 310, the outline of which is indicated by a broken line, indicates the position of the high frequency drive unit, a circle 320 indicates the position of the main drive unit, and a circle 330 indicates the position of the circular ventilation hole of the front panel of the housing 100. Nineteen compartments 250 are adapted to receive short foam blocks leaving behind a rear surface of the main drive unit and behind the circular ventilation holes. These compartments must not allow the acoustically absorbing material to contact the cone of the main drive unit (the high frequency drive unit is of enclosed construction and therefore does not require an aperture) and also the undue damping of Helmholtz resonances. This is left because free movement of air must be allowed near the ventilation holes to avoid The ventilation holes can be simple circular openings or can include short pipes, in each case approximately 50
A free compartment of 100 mm from must be left behind the inner edge of the ventilation hole.

The acoustically absorbing material helps reduce the amplitude of resonances within the individual compartments, but does result in the damping of large pressure fluctuations in the housing such that the cone of the loudspeaker drive unit damps to an unacceptably small output. You have to be careful to avoid. The proper amount of sound absorption is essentially a compromise choice for a given size and shape of the enclosure, and in some cases it may be desirable to leave some compartments free of sound absorbing material. is there.

The second enclosure according to the invention is that the ventilation holes are omitted and a full length foam block is used in the compartment near the location of the ventilation holes in the first enclosure. It is the same as the first enclosure except.

Instead of hardboard, the stiffening panel can be made of any other suitable material, with plywood being the preferred material.

The loudspeaker enclosure described with reference to the accompanying drawings may have a single loudspeaker drive unit or, instead of using two such units as described above, have more than two such units. You can

The dimensions of the various components described above are merely examples of suitable dimensions and the present invention is applicable to a variety of loudspeaker enclosures over a wide range of dimensions. It has been found that it is usually desirable to use a larger number of stiffening panels and / or thicker stiffening panels in a large enclosure as described above.

Throughout the description, including the claims, the main portion of the loudspeaker enclosure was rectangular, with one set of reinforcing panels intersecting the other set of reinforcing panels at substantially right angles. However, the invention is not limited to loudspeaker enclosures or loudspeaker systems in which the housing is shaped as described above, and the reinforcing panels do not necessarily have to be orthogonal to each other, and the housing It must be acknowledged that it does not have to abut perpendicularly to the wall. However, in this case the resulting reinforcing structure is expected to be more difficult to manufacture (unless the reinforcing panel is made of plastic material and the structure is a unitary structure), and at least some Because the stiffening panels may be adapted to extend between adjacent stiffening panels rather than opposite walls of the housing (although providing a further useful advantage over conventional enclosures), the stiffening panels may be separated from each other. , And it is expected that there will be less significant improvement over the advantages that would be gained if placed orthogonal to the housing wall.

EFFECTS OF THE INVENTION As described above, according to the present invention, it is understood that a loudspeaker enclosure having better performance than the loudspeaker enclosure of the prior art is provided.

[Brief description of drawings]

FIG. 1 is a schematic perspective view of the loudspeaker enclosure of the first system of the present invention with the front wall removed. FIG. 2 is a plan view of the first shape of the reinforcing panel used for the enclosure. FIG. 3 is a plan view of a second shape of the reinforcing panel used for the enclosure. FIG. 4 is a plan view of a third shape of the reinforcing panel used for the enclosure. FIG. 5 is a side elevational view of a fourth shape of the reinforcement panel used in the enclosure. FIG. 6 is a side elevational view of a fifth shape of the reinforcing panel used in the enclosure. FIG. 7 is a perspective view of various reinforcing panels when assembled. FIG. 8 is a front elevational view of the reinforcement panel assembly shown in FIG. 7. FIG. 9 is a schematic assembly drawing of a loudspeaker enclosure. 1, 2, 3, 4, 5 ... Reinforcement panel 21, 31, 41, 51, 55 ... Recessed portion 22, 32, 42, 52 ... Groove 23, 33, 43, 53 ... Opening 100 ... Housing 102 ...... Top wall 104 …… Bottom wall 106 …… Rear wall 108 …… Left side wall 110 …… Right side wall 200 …… Hollow reinforcement structure 250 …… Section 310 …… Circle 320 indicating the position of the high frequency drive unit …… Main Circle showing the position of the drive unit 330 ...... Circle showing the position of the ventilation holes

Claims (31)

[Claims] 1. A rectangular box-shaped housing comprising a top wall and a bottom wall, a front wall, a rear wall, a left wall and a right wall, each of which is formed by a wooden panel, and in the housing. Are arranged and extend from the top wall to the bottom wall and from the left wall to the right wall, the planes of which are arranged substantially parallel to each other and to the pair of opposing housing walls. A first set of spaced apart reinforcing panels and their faces are arranged parallel to each other and substantially parallel to the opposite pair of opposing housing walls. A hollow reinforcing structure adapted to include a second set of stiffening panels, the first set of stiffening panels being rigidly secured to the second stiffening panel to substantially include the second set of stiffening panels. Crossing over the second reinforcement panel at right angles , Whereby the reinforcing panel forms a number of rectangular parallelepiped compartments together with the housing wall, and holes are provided in the reinforcing panel to provide communication between adjacent compartments. Loudspeaker enclosure. 2. The invention as set forth in claim 1, wherein at least one set of the reinforcement panels of the set of reinforcement panels is formed as an integral structure so as to bridge the inside of the housing.
The loudspeaker enclosure according to the item. 3. A reinforcing panel of one set of the pair of reinforcing panels is formed as an integral structure so as to pass through the inside of the housing, and the other set of the pair of reinforcing panels is formed. Of reinforcing strips are made of strips, some of these strips extending between and secured to adjacent panels of the one set while the other strips are A panel extending between the sets of panels and secured to the panels and the housing wall.
The loudspeaker enclosure according to the item. 4. Reinforcement panels of both sets of said reinforcement panels are integrally formed and span the interior of said housing, each reinforcement panel including a groove, said grooves of each set of reinforcement panels. A loudspeaker enclosure as claimed in claim 2 in which is adapted to receive the other set of reinforcing panels. 5. The loudspeaker enclosure according to any one of claims 1 to 4, wherein the reinforcing panel is made of wood. 6. A loudspeaker enclosure according to claim 5, wherein said reinforcing panel is made of hardboard. 7. The loudspeaker enclosure according to claim 5, wherein the reinforcing panel is made of plywood. 8. One of claim 5, claim 6, or claim 7, wherein one of the reinforcing panels is fixed to the other set of reinforcing panels. The loudspeaker enclosure according to item 1. 9. A loudspeaker enclosure according to claim 8 wherein one set of reinforcement panels is secured to the other set of reinforcement panels by an adhesive. 10. The loudspeaker enclosure according to claim 1, wherein the reinforcing panel is made of a plastic material. 11. The loudspeaker enclosure according to claim 10, wherein the hollow reinforcing structure is an integral structure. 12. The loudspeaker enclosure according to claim 11, wherein the hollow reinforcing structure is formed by injection molding. 13. A loudspeaker enclosure according to claim 1, wherein the reinforcing panel is fixed to the housing wall. 14. The loudspeaker enclosure according to claim 13, wherein the reinforcing panel is fixed to the housing wall by an adhesive. 15. The loudspeaker enclosure according to claim 14, wherein the adhesive used is such that it is fixed in a rubbery state rather than a brittle state. 16. The loudspeaker enclosure according to claim 15, wherein the adhesive is a polyvinyl acetate adhesive. 17. A silencing material is sprayed onto an interior surface of a housing wall that is not at least designed to receive the stiffening structure and one or more drive units, the silencing material also being provided at the edge of the stiffening panel. Claims: Serving as an adhesive to secure a section to the housing wall, and for securing one set of reinforcement panels to the other set of reinforcement panels where the reinforcement structure is not a unitary structure. The loudspeaker enclosure according to any one of the first to twelfth ranges. 18. The invention according to claim 1, wherein the edge of the reinforcing panel is received in the groove of the housing wall.
The loudspeaker enclosure according to any one of 17 items. 19. A section according to any one of claims 1 to 18, wherein the section bounded by the stiffening panel is of substantially square cross section with the housing wall. Loudspeaker enclosure. 20. The loudspeaker enclosure according to claim 1, wherein each set of reinforcing panels comprises at least three reinforcing panels. 21. A loudspeaker enclosure according to any one of claims 1 to 20, wherein one of the sets of reinforcing panels consists of at least 5 reinforcing panels. 22. A method according to any one of the preceding claims, wherein at least some of said compartments contain acoustically absorbing material.
The loudspeaker enclosure according to any one of 21 items. 23. A loudspeaker enclosure according to claim 22, wherein at least a majority of said compartments contain acoustically absorbing material. 24. The loudspeaker enclosure according to claim 22, wherein the sound absorbing material is in the form of a block of open cell plastic material. 25. A loudspeaker enclosure according to claim 24, wherein said sound absorbing material is in the form of a block of open cell polyester foam or open cell polyether foam. 26. The method according to claim 22, wherein the sound absorbing material is in the form of bonded acoustic fiber, waste wool, rock wool or glass fiber. Loudspeaker enclosure. 27. The front wall of said enclosure is arranged to receive at least one loudspeaker drive unit, one set of reinforcing panels being located parallel to the top and bottom walls of said housing. 27. The loudspeaker enclosure according to any one of claims 1 to 26. 28. A loudspeaker enclosure according to any one of claims 1 to 27, wherein the housing wall is made of particle balls optionally having veneers. 29. The method according to claim 1, wherein the housing wall has a thickness in the range of 10 to 20 mm and a mass per unit area in the range of 7 to 12 kg per m ² . The loudspeaker enclosure according to any one of claims. 30. A loudspeaker enclosure according to any one of claims 1 to 29 together with one or more loudspeaker drive units mounted on the housing wall. Out loud speaker system. 31. The housing wall having one or more loudspeaker drive units mounted therein is also provided with ventilation holes whereby the loudspeaker enclosure constitutes a Helmholtz resonator. The loudspeaker enclosure according to claim 30.